Networking & Internet Technologies Chapter. 1 Overview of Data Communications and Networking
Data Communication Communication Sharing information. Sharing can be local (face to face) or remote ( over distance ) Tele communication (telephone, television, telegraphy) means communication at a distance remote communication. (tele: far) Data communication: exchange of data between two devices via transmission medium (wire cable) Communicating devices made up of : H.W( physical equipments )and S.W 2
Data Communication Effectiveness of data communication depends on : Delivery System must deliver data to correct destination. Data must be received by only intended device or user. Accuracy Data delivered accurately Timeliness Data delivered in timely manner without delay (real-time) Jitter Variation in packet arrival time, It is the uneven delay in the delivery of audio or video packets 3
Data Communication Components Data Representation Direction of Data Flow 4
Components Protocol is a set of rules that governs data communications. It represents an agreement between the communicating devices. Without a protocol two devices may be connected but not communicating Five components of data communication 5
Data Representation Text, numbers, images, audio, and video Text ASCII: 7-bit pattern (128 different symbols ) Extended ASCII: 8-bit pattern (with an extra 0 at left from to Unicode :32 bits pattern (65,536,216) symbols, which is definitely enough to represent any symbol in the world Numbers Numbers : represented by binary equivalent Images represented by matrix of pixels, small dot. The size of pixel represent the resolution Audio Audio represent sound by continuous (analog) signal Video Video can be analog or digital signal 6
Direction of Data Flow Simplex, half duplex and full duplex Simplex communication is unidirectional. (one-way-street). Only one of the two devices on a link can transmit; the other can only receive, As Keyboard and monitors 7
Direction of Data Flow Half-duplex Each station can both transmit and receive, but not at the same time. When one device is sending the other can receive and vice versa. one-lane road with two direction) 8
Direction of Data Flow Full-duplex Both stations can transmit and receive simultaneously.( telephone network) Like two way street with traffic flowing in both directions at the same time Signals going in either direction share the capacity of the link in two ways: Either the link must contain two physically separate transmission paths one for sending and other for receiving. Capacity of the channel is divided between signals traveling in both direction 9
Networks Networks Network is a set of devices (often referred to as nodes) connected by communication links. A node can be a computer, printer, or any other device can capable of sending and/or receiving data generated by other nodes on the network. Distributed Processing Most network uses distributed processing, in which a task is divided among multiple computers. Instead of a single machine responsible for all aspects of a process, separate computers handle a subset. 10
Networks Networks Network Criteria 1. Performance, 2. Reliability and 3. security Physical Structures 1. Type of connection 2. physical topology Categories of Networks (LAN, MAN and WAN) 11
Network Criteria 1. Performance – depends on Number of user Type of transmission media, Capabilities of connected H.W and the efficiency of software 2. Reliability – measured by Frequency of failure The time it takes to recover from failure Network’s robustness in a catastrophe. 3. Security : Protecting data from unauthorized access. 12
Physical Structures: Type of connection 1. Point to point A dedicated link is provided between two devices. Most of them uses an actual length of wire or cable to connect the two ends but other options,such as microwave satellite are possible Example: change television channels by infrared remote control 13
Physical Structures: Type of connection 2. Multipoint More than two devices share a single line. The capacity is shared either spatially or temporally. Spatially : Several devices can use link simultaneously Temporally : Users take turns, it is a timeshared 14
Physical Structures :physical topology The way in which a network is laid out physically. It is the geometric representation of the relationship of all the links and linking devices (nods) to one another. 15
Mesh Topology Every device has a dedicated point-to-point link to every other devices in network Mesh topology often used in MANs and WANs A fully connected mesh network has n(n-1)/2 physical channels to link n devices, Every device on the network must have n-1 I/O ports 16
Mesh topology Advantage Privacy or security (every message travels along a dedicated line, only the intended recipient sees it. Physical boundaries prevents other user from gaining access the message eliminating the traffic problems. The use of dedicated links guarantees that each connection can carry its own data load; that can occur when links must be shared by multiple devices. A mesh is robust. If one link becomes unusable, it does not incapacitate the entire system. Fault identification and fault isolation easy. This enables the network manager to discover the precise location of fault and aids in finding its cause and solution. Disadvantage Need more resource (cable & ports) Expensive to implement 17
Star Topology Each device has a dedicated point-to-point link only to a central controller (hub) Unlike a mesh, a star topology does not allow direct traffic between devices, if one device want to send data to another, it send it to the hub, which send it to other device 18
Star Topology Advantages 1. Easy to install and reconfigure and less expensive Each device need only one link and I/O port to connect it to any other devices.) 2. Robustness, If one link fails, only that link affected and other links remain active. 3. Identification and fault isolation Disadvantages Failure of central device may cause network failure Requires more cable than (Ring,bus) 19
Tree topology Is a variation of star Not every device plugs directly into the central hub. The majority of devices connect to secondary hub that in turn is connected to the central hub The advantages and disadvantages of tree topology are generally the same as those of star. The addition of secondary hubs bring more advantage : Allow more devices to be attached to a single central hub, therefore increase the distance a signal can travel between devices. 20
Bus Topology A multipoint topology Consists of cables connecting PCs or file servers Terminator attached to each end of bus cable segment to absorb signal and prevent signal reflection back on to covered path Transmitting packet across bus Detected by all nodes on segment Given time limit to reach destination 21
Bus Topology Advantages of bus design Requires less cable than other topologies Easy to install and extend bus with a workstation Disadvantages of bus topology Not secured Can become quickly congested with network traffic A fault in bus cable stops all transmissions even between devices on the same side of the problem. The damaged area reflects signals back the direction of origin, creating noise in both directions 22
Ring Topology Each device is dedicated point-to-point connection only with the two devices on either side of it Signal is passed from device to device until it reaches destination Each device functions as a repeater Repeater 23
Ring Topology Advantage Relatively easy to install and reconfigure Fault isolation is simplified Disadvantage Unidirectional traffic A break in the ring can disable the entire network. This can be solved by use dual ring 24
Hybrid topology a star backbone with three bus networks 25
Networks Categories Network category is determined by its size, ownership, the distance it cover and its physical architecture 26
LAN Privately owned and links the devices in a single office, building or campus LANs designed to allow resources to be shared between PCs or workstations. The resources may be H.W or S.W or data. In LANs one of the computers has a large capacity drive and becomes a server to other clients. SW stored on server and used as needed by the whole group. LAN size determined by licensing restrictions( No of users per copy of SW) LAN use only one type of transmission medium. The most common LAN topologies are bus, ring and star. Today, LAN speed can be 100Mbps or 1000MBps(1G) 27
MAN (metropolitan) Owned by private company or it may be a service provided by public company ( such as local tel.-company) Extended over an entire city. May be single network such as a cable television network, or it may be connected number of LANs into a large network so that resources may be shared LAN-TO-LAN. Examples: Company can use MAN to connect the LANs in all its offices throughout the city. A part of the telephone line network that can provide DSL line to the customer 28
WAN Provides long distance transmission of data, voice, image and video information over large areas ( country or whole world) In contrast to LAN, WAN may utilize public or private communication equipment's or combination 29
Switched and a Point-to-point WAN 30
Categories of Networks Based on Control Peer-to-Peer Network No single computer controls the network. Each computer is the same (a peer) to all others It is suitable for small offices. Server-Based Network The network is controlled by a special high-powered server. The server is dedicated to running the network. Print and file servers, application servers, communication servers, and directory service servers are common. 31
Interconnections of networks :internetwork An internet (small i) is two or more networks that can communicate with each other 32
The Internet Collaboration of more than 100s of thousands of interconnected networks Brief History: In mid of 1960 The A dvanced R esearch P rojects A gency (ARPA) in the department of defense was interested in finding a way to connect computers so that the researchers they funded could share their findings, to reduce costs and eliminating duplication of effort. 1n1967 ARPA presented its ideas for ARPANET, small network of connected computers 1n 1969 ARPANET was reality. Four nodes at the University Of California (at los angles and Santa Barba), University of Utah and Stand ford Research Institute connected via IMPs computers to form a network. Software called N etwork C ontrol P rotocol (NCP) provided communication between the hosts. 1n 1972, Protocol to achieve end -to-end delivery of packets, TCP. Authorities made decision to split TCP into 2 protocols: IP : Internetworking protocol to handle datagram routing and TCP : responsible for higher-level-functions such as error detection, segmentation and reassembly 33
The Internet Internet today Made up of many wide and local area networks joined by connecting devices and switching stations. Today most end users use the services of internet service providers (ISPs). 34
Protocols Protocols are set of rules that govern data communication to define What is communicated?, How it communicated?, When it is communicated? Key elements Syntax Structure or format of the data, meaning the order in which they are presented Example: A simple protocol might expect the first byte of data to be the address of the sender, the second byte to be the address of the receiver and the reset of the stream to be the message itself. Semantics Refers to the meaning of each section of bits. Example: does an address identify the route to be taken or the final destination of the message Timing When data to should be sent? How fast they can be sent? Example: If a sender produces data at 100Mpbs but the receiver can process data at only 1Mpbs, transmission will overload the receiver and data will be largely lost 35
Standards Standard provides a model for development allows for interoperability Types De jure/Formal legislated by an officially recognized body De facto Have been adopted as standers through widespread use Established by manufacturers that define the functionality of a new product or technology Standards Organizations International Organization for Standardization ( ISO ) International Telecommunication Union Telecommunication standard sector ( ITU-T ) American National Standards Institute ( ANSI ) Institute of Electrical and Electronics Engineers ( IEEE ) Electronic Industries Association ( EIA ) 36